http://commons.apache.org/proper/commons-math/: The Apache Commons Math project is a library of lightweight, self-contained mathematics and statistics components addressing the most common practical problems not immediately available in the Java programming language or commons-lang. (The Apache Software Foundation)
  • Eldar Agalarov
  • Tim Allison
  • C. Scott Ananian
  • Mark Anderson
  • Peter Andrews
  • Rémi Arntzen
  • Matt Adereth
  • Jared Becksfort
  • Michael Bjorkegren
  • Brian Bloniarz
  • John Bollinger
  • Cyril Briquet
  • Dave Brosius
  • Dan Checkoway
  • Anders Conbere
  • Charles Cooper
  • Paul Cowan
  • Benjamin Croizet
  • Larry Diamond
  • Aleksei Dievskii
  • Rodrigo di Lorenzo Lopes
  • Hasan Diwan
  • Ted Dunning
  • Ole Ersoy
  • Ajo Fod
  • John Gant
  • Ken Geis
  • Hank Grabowski
  • Bernhard Grünewaldt
  • Elliotte Rusty Harold
  • Dennis Hendriks
  • Reid Hochstedler
  • Matthias Hummel
  • Curtis Jensen
  • Bruce A Johnson
  • Ismael Juma
  • Eugene Kirpichov
  • Oleksandr Kornieiev
  • Piotr Kochanski
  • Sergei Lebedev
  • Bob MacCallum
  • Jake Mannix
  • Benjamin McCann
  • Patrick Meyer
  • J. Lewis Muir
  • Venkatesha Murthy
  • Christopher Nix
  • Fredrik Norin
  • Sean Owen
  • Sujit Pal
  • Todd C. Parnell
  • Andreas Rieger
  • Sébastien Riou
  • Bill Rossi
  • Matthew Rowles
  • Pavel Ryzhov
  • Joni Salonen
  • Michael Saunders
  • Thorsten Schaefer
  • Christopher Schuck
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  • Kim van der Linde
  • Alexey Volkov
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  • Jörg Weimar
  • Christian Winter
  • Piotr Wydrych
  • Xiaogang Zhang
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  • Mikkel Meyer Andersen
  • Bill Barker
  • Sébastien Brisard
  • Albert Davidson Chou
  • Mark Diggory
  • Robert Burrell Donkin
  • Otmar Ertl
  • Luc Maisonobe
  • Tim O'Brien
  • J. Pietschmann
  • Dimitri Pourbaix
  • Gilles Sadowski
  • Greg Sterijevski
  • Brent Worden
  • Thomas Neidhart
  • Evan Ward 
/*
 * Licensed to the Apache Software Foundation (ASF) under one or more
 * contributor license agreements.  See the NOTICE file distributed with
 * this work for additional information regarding copyright ownership.
 * The ASF licenses this file to You under the Apache License, Version 2.0
 * (the "License"); you may not use this file except in compliance with
 * the License.  You may obtain a copy of the License at
 *
 *      http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */
package org.apache.commons.math3.linear;

import org.apache.commons.math3.exception.DimensionMismatchException;
import org.apache.commons.math3.exception.MaxCountExceededException;
import org.apache.commons.math3.exception.NullArgumentException;
import org.apache.commons.math3.util.IterationManager;
import org.apache.commons.math3.util.MathUtils;


This abstract class defines an iterative solver for the linear system A
· x = b. In what follows, the residual r is defined as r = b
- A · x, where A is the linear operator of the linear system, b is the
right-hand side vector, and x the current estimate of the solution.

Since:3.0
/**
 * This abstract class defines an iterative solver for the linear system A
 * &middot; x = b. In what follows, the <em>residual</em> r is defined as r = b
 * - A &middot; x, where A is the linear operator of the linear system, b is the
 * right-hand side vector, and x the current estimate of the solution.
 *
 * @since 3.0
 */
public abstract class IterativeLinearSolver {

    
The object in charge of managing the iterations. 
/** The object in charge of managing the iterations. */
    private final IterationManager manager;

    
Creates a new instance of this class, with default iteration manager.

Params:
  • maxIterations – the maximum number of iterations
/**
     * Creates a new instance of this class, with default iteration manager.
     *
     * @param maxIterations the maximum number of iterations
     */
    public IterativeLinearSolver(final int maxIterations) {
        this.manager = new IterationManager(maxIterations);
    }

    
Creates a new instance of this class, with custom iteration manager.

Params:
  • manager – the custom iteration manager
Throws:
/**
     * Creates a new instance of this class, with custom iteration manager.
     *
     * @param manager the custom iteration manager
     * @throws NullArgumentException if {@code manager} is {@code null}
     */
    public IterativeLinearSolver(final IterationManager manager)
        throws NullArgumentException {
        MathUtils.checkNotNull(manager);
        this.manager = manager;
    }

    
Performs all dimension checks on the parameters of solve and solveInPlace, and throws an exception if one of the checks fails. 
Params:
  • a – the linear operator A of the system
  • b – the right-hand side vector
  • x0 – the initial guess of the solution
Throws:
/**
     * Performs all dimension checks on the parameters of
     * {@link #solve(RealLinearOperator, RealVector, RealVector) solve} and
     * {@link #solveInPlace(RealLinearOperator, RealVector, RealVector) solveInPlace},
     * and throws an exception if one of the checks fails.
     *
     * @param a the linear operator A of the system
     * @param b the right-hand side vector
     * @param x0 the initial guess of the solution
     * @throws NullArgumentException if one of the parameters is {@code null}
     * @throws NonSquareOperatorException if {@code a} is not square
     * @throws DimensionMismatchException if {@code b} or {@code x0} have
     * dimensions inconsistent with {@code a}
     */
    protected static void checkParameters(final RealLinearOperator a,
        final RealVector b, final RealVector x0) throws
        NullArgumentException, NonSquareOperatorException,
        DimensionMismatchException {
        MathUtils.checkNotNull(a);
        MathUtils.checkNotNull(b);
        MathUtils.checkNotNull(x0);
        if (a.getRowDimension() != a.getColumnDimension()) {
            throw new NonSquareOperatorException(a.getRowDimension(),
                                                       a.getColumnDimension());
        }
        if (b.getDimension() != a.getRowDimension()) {
            throw new DimensionMismatchException(b.getDimension(),
                                                 a.getRowDimension());
        }
        if (x0.getDimension() != a.getColumnDimension()) {
            throw new DimensionMismatchException(x0.getDimension(),
                                                 a.getColumnDimension());
        }
    }

    
Returns the iteration manager attached to this solver.

Returns:the manager
/**
     * Returns the iteration manager attached to this solver.
     *
     * @return the manager
     */
    public IterationManager getIterationManager() {
        return manager;
    }

    
Returns an estimate of the solution to the linear system A · x =
b.

Params:
  • a – the linear operator A of the system
  • b – the right-hand side vector
Throws:
Returns:a new vector containing the solution
/**
     * Returns an estimate of the solution to the linear system A &middot; x =
     * b.
     *
     * @param a the linear operator A of the system
     * @param b the right-hand side vector
     * @return a new vector containing the solution
     * @throws NullArgumentException if one of the parameters is {@code null}
     * @throws NonSquareOperatorException if {@code a} is not square
     * @throws DimensionMismatchException if {@code b} has dimensions
     * inconsistent with {@code a}
     * @throws MaxCountExceededException at exhaustion of the iteration count,
     * unless a custom
     * {@link org.apache.commons.math3.util.Incrementor.MaxCountExceededCallback callback}
     * has been set at construction of the {@link IterationManager}
     */
    public RealVector solve(final RealLinearOperator a, final RealVector b)
        throws NullArgumentException, NonSquareOperatorException,
        DimensionMismatchException, MaxCountExceededException {
        MathUtils.checkNotNull(a);
        final RealVector x = new ArrayRealVector(a.getColumnDimension());
        x.set(0.);
        return solveInPlace(a, b, x);
    }

    
Returns an estimate of the solution to the linear system A · x =
b.

Params:
  • a – the linear operator A of the system
  • b – the right-hand side vector
  • x0 – the initial guess of the solution
Throws:
Returns:a new vector containing the solution
/**
     * Returns an estimate of the solution to the linear system A &middot; x =
     * b.
     *
     * @param a the linear operator A of the system
     * @param b the right-hand side vector
     * @param x0 the initial guess of the solution
     * @return a new vector containing the solution
     * @throws NullArgumentException if one of the parameters is {@code null}
     * @throws NonSquareOperatorException if {@code a} is not square
     * @throws DimensionMismatchException if {@code b} or {@code x0} have
     * dimensions inconsistent with {@code a}
     * @throws MaxCountExceededException at exhaustion of the iteration count,
     * unless a custom
     * {@link org.apache.commons.math3.util.Incrementor.MaxCountExceededCallback callback}
     * has been set at construction of the {@link IterationManager}
     */
    public RealVector solve(RealLinearOperator a, RealVector b, RealVector x0)
        throws NullArgumentException, NonSquareOperatorException,
        DimensionMismatchException, MaxCountExceededException {
        MathUtils.checkNotNull(x0);
        return solveInPlace(a, b, x0.copy());
    }

    
Returns an estimate of the solution to the linear system A · x =
b. The solution is computed in-place (initial guess is modified).

Params:
  • a – the linear operator A of the system
  • b – the right-hand side vector
  • x0 – initial guess of the solution
Throws:
Returns:a reference to x0 (shallow copy) updated with the solution
/**
     * Returns an estimate of the solution to the linear system A &middot; x =
     * b. The solution is computed in-place (initial guess is modified).
     *
     * @param a the linear operator A of the system
     * @param b the right-hand side vector
     * @param x0 initial guess of the solution
     * @return a reference to {@code x0} (shallow copy) updated with the
     * solution
     * @throws NullArgumentException if one of the parameters is {@code null}
     * @throws NonSquareOperatorException if {@code a} is not square
     * @throws DimensionMismatchException if {@code b} or {@code x0} have
     * dimensions inconsistent with {@code a}
     * @throws MaxCountExceededException at exhaustion of the iteration count,
     * unless a custom
     * {@link org.apache.commons.math3.util.Incrementor.MaxCountExceededCallback callback}
     * has been set at construction of the {@link IterationManager}
     */
    public abstract RealVector solveInPlace(RealLinearOperator a, RealVector b,
        RealVector x0) throws NullArgumentException, NonSquareOperatorException,
        DimensionMismatchException, MaxCountExceededException;
}